https://scholarlywiki.org/index.php?action=history&feed=atom&title=Physics%3AQuantum_geometryPhysics:Quantum geometry - Revision history2026-05-14T03:44:19ZRevision history for this page on the wikiMediaWiki 1.43.1https://scholarlywiki.org/index.php?title=Physics:Quantum_geometry&diff=843&oldid=previmported>WikiHarold: url2023-03-06T05:01:36Z<p>url</p>
<table style="background-color: #fff; color: #202122;" data-mw="interface">
<col class="diff-marker" />
<col class="diff-content" />
<col class="diff-marker" />
<col class="diff-content" />
<tr class="diff-title" lang="en">
<td colspan="2" style="background-color: #fff; color: #202122; text-align: center;">← Older revision</td>
<td colspan="2" style="background-color: #fff; color: #202122; text-align: center;">Revision as of 05:01, 6 March 2023</td>
</tr><tr><td colspan="4" class="diff-notice" lang="en"><div class="mw-diff-empty">(No difference)</div>
</td></tr>
<!-- diff cache key my_wiki:diff:1.41:old-352:rev-843 -->
</table>imported>WikiHaroldhttps://scholarlywiki.org/index.php?title=Physics:Quantum_geometry&diff=352&oldid=previmported>WikiHarold: url2023-03-06T05:01:36Z<p>url</p>
<p><b>New page</b></p><div>{{short description|Set of mathematical concepts propagating geometric concepts}}<br />
{{Quantum mechanics}}<br />
<br />
In [[Physics:Theoretical physics|theoretical physics]], '''quantum geometry''' is the set of mathematical concepts generalizing the concepts of [[Geometry|geometry]] whose understanding is necessary to describe the physical phenomena at distance scales comparable to the [[Planck length]]. At these distances, [[Physics:Quantum mechanics|quantum mechanics]] has a profound effect on physical phenomena.<br />
<br />
==Quantum gravity==<br />
<br />
{{Main|Physics:Quantum gravity}}<br />
<br />
Each theory of [[Physics:Quantum gravity|quantum gravity]] uses the term "quantum geometry" in a slightly different fashion. [[Physics:String theory|String theory]], a leading candidate for a quantum theory of gravity, uses the term quantum geometry to describe exotic phenomena such as [[Physics:T-duality|T-duality]] and other geometric dualities, [[Mirror symmetry (string theory)|mirror symmetry]], [[Topology|topology]]-changing transitions{{clarify|date=May 2016}}, minimal possible distance scale, and other effects that challenge intuition. More technically, quantum geometry refers to the shape of a spacetime manifold as experienced by D-branes which includes quantum corrections to the [[Physics:Metric tensor|metric tensor]], such as the worldsheet [[Physics:Instanton|instanton]]s. For example, the quantum volume of a cycle is computed from the mass of a brane wrapped on this cycle.<br />
<br />
In an alternative approach to quantum gravity called [[Physics:Loop quantum gravity|loop quantum gravity]] (LQG), the phrase "quantum geometry" usually refers to the [[Scientific formalism|formalism]] within LQG where the observables that capture the information about the geometry are now well defined operators on a [[Hilbert space]]. In particular, certain physical [[Physics:Observable|observable]]s, such as the area, have a discrete spectrum. It has also been shown that the loop quantum geometry is non-commutative.<ref>{{citation<br />
| last1 = Ashtekar | first1 = Abhay<br />
| last2 = Corichi | first2 = Alejandro<br />
| last3 = Zapata | first3 = José A.<br />
| doi = 10.1088/0264-9381/15/10/006<br />
| issue = 10<br />
| journal = Classical and Quantum Gravity<br />
| mr = 1662415<br />
| pages = 2955–2972<br />
| title = Quantum theory of geometry. III. Non-commutativity of Riemannian structures<br />
| volume = 15<br />
| year = 1998|arxiv = gr-qc/9806041 |bibcode = 1998CQGra..15.2955A | s2cid = 250895945<br />
}}.</ref><br />
<br />
It is possible (but considered unlikely) that this strictly quantized understanding of geometry will be consistent with the quantum picture of geometry arising from string theory.<br />
<br />
Another, quite successful, approach, which tries to reconstruct the geometry of space-time from "first principles" is Discrete Lorentzian quantum gravity.<br />
<br />
==Quantum states as differential forms==<br />
<br />
<br />
Differential forms are used to express quantum states, using the wedge product:<ref>''The Road to Reality'', Roger Penrose, Vintage books, 2007, {{ISBN|0-679-77631-1}}</ref><br />
<br />
:<math>|\psi\rangle = \int \psi(\mathbf{x},t) \, |\mathbf{x},t\rangle \, \mathrm{d}^3\mathbf{x} </math><br />
<br />
where the position vector is<br />
<br />
:<math>\mathbf{x} = (x^1,x^2,x^3) </math><br />
<br />
the differential [[Volume element|volume element]] is<br />
<br />
:<math>\mathrm{d}^3\mathbf{x} = \mathrm{d}x^1 \!\wedge \mathrm{d}x^2 \!\wedge \mathrm{d}x^3</math><br />
<br />
and {{math|''x''<sup>1</sup>, ''x''<sup>2</sup>, ''x''<sup>3</sup>}} are an arbitrary set of coordinates, the upper [[Index notation|indices]] indicate [[Covariance and contravariance of vectors|contravariance]], lower indices indicate [[Covariance and contravariance of vectors|covariance]], so explicitly the quantum state in differential form is:<br />
<br />
:<math>|\psi\rangle = \int \psi(x^1,x^2,x^3,t) \, |x^1,x^2,x^3,t\rangle \, \mathrm{d}x^1 \!\wedge \mathrm{d}x^2 \!\wedge \mathrm{d}x^3</math><br />
<br />
The overlap integral is given by:<br />
<br />
:<math>\langle\chi|\psi\rangle = \int \chi^* \psi ~ \mathrm{d}^3\mathbf{x}</math><br />
<br />
in differential form this is<br />
<br />
:<math>\langle\chi|\psi\rangle = \int \chi^* \psi ~ \mathrm{d}x^1 \!\wedge \mathrm{d}x^2 \!\wedge \mathrm{d}x^3</math><br />
<br />
The probability of finding the particle in some region of space {{math|''R''}} is given by the integral over that region:<br />
<br />
:<math>\langle\psi|\psi\rangle = \int_R \psi^* \psi ~ \mathrm{d}x^1 \!\wedge \mathrm{d}x^2 \!\wedge \mathrm{d}x^3</math><br />
<br />
provided the wave function is [[Wave function|normalized]]. When {{math|''R''}} is all of 3d position space, the integral must be {{math|1}} if the particle exists.<br />
<br />
Differential forms are an approach for describing the geometry of curves and [[Surface (mathematics)|surface]]s in a coordinate independent way. In [[Physics:Quantum mechanics|quantum mechanics]], idealized situations occur in rectangular Cartesian coordinates, such as the [[Physics:Potential well|potential well]], [[Physics:Particle in a box|particle in a box]], [[Physics:Quantum harmonic oscillator|quantum harmonic oscillator]], and more realistic approximations in spherical polar coordinates such as electrons in atoms and molecules. For generality, a formalism which can be used in any coordinate system is useful.<br />
<br />
==See also==<br />
* [[Noncommutative geometry]]<br />
<br />
==References==<br />
{{reflist}}<br />
<br />
==Further reading==<br />
<br />
* ''Supersymmetry'', Demystified, P. Labelle, McGraw-Hill (USA), 2010, {{ISBN|978-0-07-163641-4}}<br />
* ''Quantum Mechanics'', E. Abers, Pearson Ed., Addison Wesley, Prentice Hall Inc, 2004, {{ISBN|9780131461000}}<br />
* ''Quantum Mechanics Demystified'', D. McMahon, Mc Graw Hill (USA), 2006, {{ISBN|0-07-145546 9}}<br />
* ''Quantum Field Theory'', D. McMahon, Mc Graw Hill (USA), 2008, {{ISBN|978-0-07-154382-8}}<br />
<br />
==External links==<br />
*[http://cgpg.gravity.psu.edu/people/Ashtekar/articles/spaceandtime.pdf Space and Time: From Antiquity to Einstein and Beyond]<br />
*[http://cgpg.gravity.psu.edu/people/Ashtekar/articles/qgfinal.pdf Quantum Geometry and its Applications]<br />
<br />
{{Physics-footer}}<br />
{{Quantum mechanics topics|state=expanded}}<br />
[[Category:Quantum gravity]]<br />
[[Category:Quantum mechanics]]<br />
[[Category:Mathematical physics]]<br />
<br />
{{Sourceattribution|Quantum geometry}}</div>imported>WikiHarold